材料科学
纳米晶材料
合金
磁性合金
微观结构
磁性形状记忆合金
非晶态金属
结晶
冶金
相(物质)
纳米晶
磁各向异性
维氏硬度试验
饱和(图论)
磁畴
延展性(地球科学)
无定形固体
超塑性
复合材料
感应加热
制作
各向异性
再结晶(地质)
极限抗拉强度
亚稳态
矫顽力
内应力
作者
Jing Ding,Cong Liu,Zongzhen Li,Wenchao Liu,Xiaolong Wang,J. Tian,Sun Lu,Shengli Zhu
标识
DOI:10.1007/s41230-025-5100-3
摘要
A cost-effective Fe-P-C nanocrystalline alloy (Fe85P9C6) was developed via melt-spinning by eliminating expensive alloying elements and post-annealing steps. The microstructure consists of an amorphous matrix with uniformly dispersed nanocrystalline clusters, featuring an average size of approximately 5 nm. This dual-phase structure remains thermally stable up to 569 K and results in excellent magnetic and mechanical performance, including a high saturation magnetic induction of 1.69 T, Vickers hardness of 621 HV, and outstanding bending ductility. Crystallization proceeds via the transformation of a metastable fcc-(Fe,P,C) phase into α-Fe, Fe3C, and Fe3P, driven by internal stress arising from atomic size mismatch. Continuous heating and cooling transformation diagrams further reveal that this process can be precisely controlled to optimize phase evolution. The high Fe content and stress-relaxed nanocrystalline clusters contribute to enhanced in-plane magnetic anisotropy and rapid domain response. This simplified, annealing-free approach not only reduces material and processing costs but also provides a viable pathway for scalable fabrication of next-generation soft magnetic alloys with superior performance and manufacturability.
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